Medical device assembly

ABSTRACT

Medical device assemblies having a connection mechanism for securely connecting a hub to fluid storage containers in a luer slip relationship are described. An exemplary medical device includes a hub forming a cavity, a second indicating element disposed within the cavity that engages the hub. Additional features of the medical device include a second indicating element contoured to form a line contact with the hub. In a specific configuration, the hub includes a first indicating element attached to the hub and extending proximally into the cavity having a protrusion. In a more specific configuration, the medical device includes a fluid storage container that has an indication system for visually indicating optimal fluid-tight engagement of the hub and the fluid storage container.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. patent application Ser. No.15/784,896, filed on Oct. 16, 2017, now U.S. Pat. No. 10,426,899 issuedon Oct. 1, 2019, which is a continuation of U.S. patent application Ser.No. 14/537,999, filed on Nov. 11, 2014, now U.S. Pat. No. 9,789,265,issued on Oct. 17, 2017, which is continuation of U.S. patentapplication Ser. No. 12/512,532, filed on Jul. 30, 2009, now U.S. Pat.No. 8,915,890, issued on Dec. 23, 2014, the disclosures of which areincorporated herein by reference in their entirety.

TECHNICAL FIELD

Aspects of the present invention relate to medical devices having a luerslip mechanism for connection to a fluid storage container.

BACKGROUND

Fluid storage containers, such as syringes, having a luer fitting orconnection are often assembled with hubs or luer fittings. Two commonmechanisms used to connect the hubs to the syringes include the “luerlock” and “luer slip” mechanisms.

The luer lock mechanism generally includes a fluid storage containerwith a male fitting in co-axial relation with an internally threadedcollar. A cooperating hub or female luer lock fittings have externallugs for engaging the internally threaded collar of the male conicalfitting, upon application of a twisting force or torque force to thehub.

The luer slip fitting generally includes a fluid storage container witha male fitting without a threaded collar. Cooperating hubs or femaleluer slip fittings typically have an internal surface which slides overthe external surface of the male fitting. The hub is attached to themale fitting in a friction fit or interference fit relationship. Toattach the hub to the male fitting, the user must apply enough forcewhen sliding the hub over the male fitting to create a fluid-tightrelationship between the hub and male fitting. Failure to securelyconnect the hub and medical device can result in “pop offs,” where theunsecured hub detaches from the male fitting during use.

A medical device with a connection mechanism for securely connecting ahub to fluid storage containers in a luer slip relationship, as definedherein, presents a viable solution to these issues. In addition, thereis a need for a mechanism that indicates such secure connection betweena hub and fluid container.

SUMMARY

A first aspect of the present invention pertains to medical devices foruse with fluid storage containers. Medical devices have structure thatforms line contact interactions between a first indicating element ofthe hub and a second indicating element of the hub when the fluidstorage container is securely connected to the hub. As used herein, theterm “line contact” shall include contact between two surfaces at two ormore points, wherein one or both of the surfaces are compressible and/ornon-compressible. As used herein, the term “surface contact” or “pointcontact” shall include contact between two surfaces at a single point,wherein one or both of the surfaces are compressible and/ornon-compressible. In one or more embodiments, the medical deviceincludes a hub with a distal end with an opening, an open proximal endand a sidewall extending from the distal end to the proximal end forminga cavity. The medical device further includes a first indicating elementattached to the distal end of the hub extending into the cavity and asecond indicating element disposed within the cavity. In one or moreembodiments, one of either the first indicating element or the secondindicating element is flexible.

In one or more embodiments, the opening of the hub at the distal end isin fluid communication with the cavity. The hub may optionally include aneedle cannula attached to its distal end and extending in the distaldirection. The needle cannula used with one or more embodiments,includes a proximal end, a distal end and a lumen therethrough in fluidcommunication with the cavity. Alternative embodiments of the hub mayinclude a safety cap covering the needle cannula. In a specificembodiment, the hub may include a coaxial wall extending from the distalend of the hub that forms a channel between the coaxial wall and thesidewall of the hub for receiving the safety cap.

The first indicating element includes a distal end attached to thedistal end of the hub and a proximal end that extends into the cavity ofthe hub. In one or more embodiments, the distal end of the firstindicating element surrounds the opening in the distal end of the hub.The first indicating element of one or more embodiments forms a recesswith the sidewall of the hub. The first indicating element may alsoinclude an outwardly radially extending protrusion. In one or moreembodiments the protrusion is disposed on the outside surface of thefirst indicating element and extends into the recess formed between thefirst indicating element and the sidewall of the hub.

The second indicating element of one or more embodiments includes anopen proximal end, an open distal end and a body extending from the openproximal end to the open distal end. The body includes an inside surfacethat defines a hollow interior. The body of one or more embodiments ofthe second indicating element may be hollow and cylindrical.

In one or more embodiments, the hollow interior is sized and shaped toenvelope or receive the first indicating element. In a more specificembodiment, the hollow interior allows the body of the second indicatingelement to enter the recess formed between the first indicating elementand the sidewall of the hub. The body of the second indicating elemententers the recess upon application of a distally directed force on thesecond indicating element. In one or more embodiments, the protrusion ofthe first indicating element prevents the body from entering the recessuntil a pre-determined distally-directed force is applied to the secondindicating element. In a specific embodiment, the protrusion is shapedand/or adapted to advance proximally into the hollow interior of thesecond indicating element as the body of the second indicating elemententers the recess.

In accordance with one or more embodiments the inside surface of thesecond indicating element or the cross-sectional width formed by theinside surface is contoured to form a line contact interaction with thefirst indicating element upon application of a force on the secondindicating element in the distal direction. As used herein, the term“cross-sectional width” shall include the longest distance between twopoints on the circumference or edge of the cross-section of an objecthaving a circular and non-circular cross-section. The two points may belocated on the interior or exterior surface circumference or edge of thecross-section of the object. It should be recognized that“cross-sectional width” of objects having a circular cross-section maybe referred to as the “diameter” of the object. The terms“cross-sectional width” and “diameter” may be used interchangeably forobjects having a circular cross-section.

In a specific embodiment, the inside surface includes a first diameterportion adjacent to the open distal end of the second indicatingelement. The inside surface may also include a second diameter portionhaving an axial length extending from the first diameter portion to theopen proximal end. In one or more embodiments, the diameter of theinside surface increases along the second diameter portion from thefirst diameter portion toward the open proximal end of the secondindicating element.

In accordance with one or more embodiments, the second indicatingelement includes an inside surface defining a cross-sectional width. Theinside surface includes a tapered portion adjacent to the open distalend of the body, a ramped portion distally adjacent to the taperedportion, an enlarged portion adjacent the open proximal end of the body.In one or more embodiments, the ramped portion has an axial lengthextending from the tapered diameter portion toward the enlarged portion.In a specific embodiment, the cross-sectional width of the insidesurface increases along the axial length of the ramped portion from thetapered portion toward the enlarged portion. The second indicatingelement of one or more embodiments is adapted to slide distally over thefirst indicating element, as will be described herein. In a specificembodiment, the ramped portion of the inside surface of the secondindicating element forms a line contact interaction with the firstindicating element as the second indicating element receives the firstindicating element. In a more specific embodiment, the axial length ofthe ramped portion may be reduced to provide tactile feedback uponfluid-tight engagement of a fluid storage container and a hub.

The second indicating element with a tapered portion may be utilizedwith a first indicating element having a protrusion shaped and/oradapted to slide proximally past the tapered portion upon application ofa pre-determined force on the second indicating element in a distaldirection relative to the first indicating element. Alternatively, theprotrusion may be shaped and/or adapted to prevent the second indicatingelement from engaging the first indicating element or sliding distallyover the first indicating element until a pre-determined force isapplied to the second indicating element in a proximal directionrelative to the first indicating element.

The open distal end of one or more embodiments of the second indicatingelement includes a continuous or solid perimeter. In one or moreembodiments, the continuous or solid perimeter has a circular form thatis maintained upon application of a distally directed force on thesecond indicating element until the hub and the fluid container are influid-tight engagement.

One or more embodiments of the medical devices described herein mayincorporate means for indicating application of a force on the hubsufficient to result in fluid-tight engagement of the hub with a fluidstorage device. In accordance with one or more embodiments, the meansforms at least two contact points with the hub. For example, the hub mayinclude a first indicating element at its distal end extendingproximally into the cavity from the opening and the means forms at leasttwo contact points with the second indicating element during applicationof the force on the hub. In one or more embodiments the first indicatingelement may also include a radially extending protrusion and the meansfor indicating comprises a hollow cylindrical body having a proximalend, a distal end and an inside surface extending from the proximal endto the distal end that has a diameter that increases from the distal endto the proximal end. In a specific embodiment, the hollow cylindricalbody has a circular cross-section that maintains its circular shapeduring application of the required force on the hub. In a more specificembodiment, the means for indicating produces tactile feedback uponfluid-tight engagement of the hub and the fluid storage device.

A second aspect of the present invention pertains to a feature thatincludes a visual indicator. The visual indicator may be used with oneor more embodiments of the medical device described herein. The visualindicator is disposed on a fluid storage device, for example, adjacentto the opening of the fluid storage device. In one or more embodiments,the fluid storage device includes a syringe barrel with a luer tip andthe visual indicator is disposed on the tip. In alternative embodiments,the fluid storage device includes a male luer connector and the visualindicator is disposed on the male luer connector. The visual indicatoris disposed at a location on the tip such that it is fully visible priorto fluid-tight engagement of the fluid-transfer device and the medicaldevice or hub of the medical device. The first predefined portion of thevisual indicator is also visible when the connection between the fluidstorage device and the medical device is under tightened. In accordancewith one or more embodiments, a second predefined portion which is lessthan the first predefined portion of the visual indicator is visibleupon optimal tightening and/or fluid-tight engagement of the fluidstorage device and the hub. In a specific embodiment, the visualindicator is not visible when the connection between the fluid storagedevice and the hub is over tightened. The fluid storage devicesdescribed herein may be utilized with one or more embodiments of themedical devices described herein regardless of whether the medicaldevice utilizes the visual indication feature.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a medical device assembly according to one or moreembodiments of the invention shown attached to a fluid storagecontainer;

FIG. 2 shows an exploded view of the assembly of FIG. 1;

FIG. 3 is an exploded cross-sectional view of the hub, second indicatingelement and fluid storage container shown in FIG. 1 taken along line3-3;

FIG. 4 is an enlarged view of the second indicating element shown inFIG. 2;

FIG. 5 is a perspective cross-sectional view of the second indicatingelement shown in FIG. 4 taken along line 5-5;

FIG. 6 is an enlarged sectional view of the second indicating elementshown in FIG. 3;

FIG. 7 is a cross-sectional view of the second indicating element shownin FIG. 4 taken along line 7-7;

FIG. 8 is a cross-sectional view of an alternative embodiment of thesecond indicating element;

FIG. 9A is an enlarged sectional view of the hub shown in FIG. 3;

FIG. 9B is an enlarged sectional view of a hub according to analternative embodiment;

FIG. 10 is a cross-sectional view of the hub, second indicating elementand the fluid storage container shown in FIG. 3 partially assembled;

FIG. 11 is an enlarged view of FIG. 10;

FIG. 12 illustrates FIG. 10 after application of an initial proximallydirected force on the hub relative to the fluid storage container;

FIG. 13 is an enlarged view of FIG. 12;

FIG. 14 illustrates FIG. 12 after continued application of a proximallydirected force on the hub relative to the fluid storage container;

FIG. 15 is an enlarged view of FIG. 14;

FIG. 16 illustrates FIG. 13 after the hub and the fluid storagecontainer are in fluid-tight engagement;

FIG. 17 is an enlarged view of FIG. 16;

FIG. 18A is an cross-sectional view of the second indicating element ofFIG. 8 advancing distally past an alternative embodiment of the hub uponapplication of a proximally directed force on the hub relative to thefluid storage container;

FIG. 18B is a cross-sectional view of the second indicating element ofFIG. 8 advancing distally past the alternative embodiment of the hub ofFIG. 18A upon continued application of a proximally directed force onthe hub relative to the fluid storage container;

FIG. 19 illustrates a partially assembled view of a medical deviceaccording to a second embodiment of the invention;

FIG. 20 shows the medical device of FIG. 19 in an optimal assembly;

FIG. 21 shows the medical device of FIG. 19 in an over-tightenedassembly; and

FIG. 22 shows the medical device of FIG. 19 in an under-tightenedassembly.

DETAILED DESCRIPTION

Before describing several exemplary embodiments of the invention, it isto be understood that the invention is not limited to the details ofconstruction or process steps set forth in the following description.The invention is capable of other embodiments and of being practiced orbeing carried out in various ways.

One aspect of the present invention provides for a medical deviceassembly that may be connected or attached in fluid-tight engagementwith a fluid storage container. The medical device assembly of one ormore embodiments may utilize a first indicating element and/or a secondindicating element as a means for indicating fluid-tight engagement witha fluid storage container. One or more embodiments of the medical deviceassembly include a hub and means for indicating application of a forceon the hub sufficient to result in fluid tight engagement with a fluidstorage container. The means for indicating may be utilized duringengagement of the medical device assembly and the fluid storagecontainer in a luer slip configuration. The embodiments of the medicaldevice assemblies described herein may be used with an optional needlecannula and/or an optional needle tip cap.

FIGS. 1-21 illustrate a medical device assembly according to one or moreembodiments. It will be understood that medical device assembly may beused with fluid storage containers such as syringe barrels, needlelessIV sets, or other devices that can be used to store and/or transfermedication or other liquid. In one or more embodiments, the fluidstorage container includes an opening providing access to the contentsof the container. The opening may include a male luer fitting or may beotherwise configured for use with the medical device assembly.

FIGS. 1-21 illustrate a medical device assembly according to theinvention, including a hub 160 having means for indicating applicationof a force on the hub sufficient to result in fluid tight engagementwith a fluid storage container 140. In one or more embodiments, themeans for indicating application of such a force forms at least twocontact points with the hub during application of the force. In one ormore embodiments, the means for indicating application of such a forceincludes a first indicating element 170 attached to or integrally formedwith the hub and/or a second indicating element 180 disposed within thehub 160.

FIGS. 1-7 show an embodiment of the medical device assembly thatincludes an optional needle cannula 132 attached to a hub 160. FIG. 1-7also show an optional fluid storage container 140 in the form of asyringe barrel attached to the hub to form a fluid delivery system 100.In one or more embodiments, the fluid storage container 140 has asidewall 142 with an inside surface 144 that defines a chamber 146 forholding the contents of the container, which may include medication. Thecontainer 140 includes an open proximal end 141 and a distal end 149 anda distal wall 148. The distal wall 148 includes a luer tip 150 having anopening 152 in fluid communication with the chamber 146. The fluidstorage container 140 may include a plunger rod 120 inserted into theproximal end 141 of the fluid storage container 140. It is to beunderstood that the configuration shown is merely exemplary, and thecomponents can be different in shape and size than shown.

The hub 160 shown more clearly in FIG. 9A includes an open proximal end161 and a distal end 169 that includes the optional needle cannula 132having a lumen 134 therethrough. The hub 160 includes a sidewall 164extending from the distal end 169 toward the open proximal end 161 anddefining a cavity 166. The distal end 169 includes a passageway 130therethrough in fluid communication with the lumen 134 of the optionalneedle cannula 132. As more clearly shown in FIG. 10, a secondindicating element 180 is disposed within the cavity 166 of the hub 160.

The distal end 169 of the hub 160 further includes a first indicatingelement 170 having a distal end 179 attached to the distal end 169 ofthe hub 160 and a free proximal end 171 extending proximally into thecavity 166. In a specific embodiment, the first indicating element 170is permanently attached to the distal end 169 of the hub. In a morespecific embodiment, the first indicating element 170 is integrallyformed with the hub 160. In an alternative embodiment, the firstindicating element 170 is a separate component that may be attached oraffixed to the distal end 169 of the hub. The first indicating element170 of one or more embodiments is substantially free of threads andforms an interference fit engagement with the second indicating element180, as will be more fully described below. The first indicating element170 forms a recess 163 with the sidewall 164. The recess 163 may extendfrom the distal end 169 of the hub to the free proximal end 171 of thefirst indicating element 170. In one or more embodiments, the firstindicating element may be in the form of a second sidewall formedcoaxially with the sidewall 164 of the hub, forming peripheral recesswith the sidewall 164 of the hub. In a specific embodiment, thecoaxially formed second sidewall may encircle or surround the passageway130. In a more specific embodiment, the first indicating element mayinclude a cantilevered beam attached to the distal end 169 of the hubadjacent to the passageway 130 and extending into the cavity 166.

The recess 163 is shaped to receive the second indicating element 180when the hub is attached to a fluid storage container. The firstindicating element 170 includes at least one protrusion 175 extendingradially outwardly from the outer surface of the first indicatingelement 170 into the recess 163. The protrusion 175 may be a singleextending portion or may be a ridge formed concentrically around thefirst indicating element 170. In one or more embodiments, the locationof the protrusion may be modified to indicate fluid tight connectionwith fluid storage containers having different shapes and for use withsecond indicating elements 180 with different sizes and shapes.

In the alternative embodiment shown in FIG. 9B, the medical device ofthe invention may include a hub 260 with a needle cannula 132 whereinthe hub 260 is configured to incorporate one or more components toprevent contamination and accidental sticking and/or to protect theneedle cannula 132, such as a needle tip cap (not shown). The hub 260includes a distal end 269 with a passageway 230 therethrough, an openproximal end 261, and a sidewall 264 extending from the distal end 269and the proximal end 261 that defines a cavity 266. The hub 260 includesfirst indicating element 270 for indicating fluid-tight engagementbetween the hub 260 and a fluid storage container. The hub 260 includesa coaxial wall 267 formed around the sidewall 264 at the distal end 269.The coaxial wall 267 forms a channel 268 for receiving a needle tip cap(not shown).

The needle cannula 132 may be made of various materials known in theart, including metals such as stainless steel, and may be held in thehub 160 or 260 using known manufacturing methods. For example, adhesivesmay be used to hold the needle. The hub may be manufactured using knownmethods such as injection molding and may be made of injection moldableplastic such as polypropylene, polyethylene, polycarbonate andcombinations thereof. The needle cannula and hub may also be integrallyformed of thermoplastic material. The sidewall 164 of the hub may alsobe shaped to attach to a variety of fluid storage containers.

The shape of the hub may be modified to form an interference fit with aselected fluid storage container in a luer slip configuration. Forexample, the hub may be shaped to have a frusto-conical shape to form aluer slip configuration with the tip of a fluid storage container (asshown in FIGS. 9-17). The hub may also be shaped to be used withstandard luer slip fittings or other luer fittings known in the art. Inone or more embodiments, the sidewall 164 of the hub 160 may be free ofany threads for engagement with the fluid storage container in a luerlock configuration.

As shown more clearly in FIGS. 10-17, the second indicating element 180is disposed within the cavity 166 of the hub 160. Referring to FIGS.4-7, the second indicating element 180 includes an open proximal end 181and an open distal end 189. The second indicating element 180 alsoincludes a hollow body 182 having an axial length and an inside surface184 defining a hollow interior 186 extending from the distal end 189 tothe proximal end 181. In one or more embodiments, the second indicatingelement 180 is shaped and positioned to ensure or to facilitatefluid-tight engagement of the hub 160 and a fluid storage container. Ina specific embodiment, the second indicating element 180 is positionedwithin the cavity 166 of the hub 160 so that when the hub 160 is placedover the opening of a fluid storage container, for example, the tip 150of a fluid storage container 140, the proximal end 181 of the secondindicating element 180 abuts the tip 150, while the distal end 189 ofthe second indicating element 180 is adjacent to and/or contacts theproximal end 171 of the first indicating element 170, as more clearlyshown in FIGS. 10-11.

In one or more embodiments, during assembly, the tip 150 is disposedadjacent to the proximal end 181 of the second indicating element 180and does not enter the hollow interior 186 of the second indicatingelement 180 during assembly of the fluid storage container 140 and thehub 160. In accordance with one or more embodiments, the secondindicating element 180 is shaped and configured to require a user toapply a pre-determined force on the hub 160 in the proximal directiontoward the fluid storage container 140 or a pre-determined force on thefluid storage container 140 in the distal direction toward the hub 160to allow the second indicating element 180 to advance distally over thefirst indicating element 170 and the protrusion 175 disposed on theouter surface of the first indicating element 170, as shown in FIGS.10-17. Application of this pre-determined force results in thedisplacement of the second indicating element 180 within the cavity 166into the recess 163, thereby indicating the point at which the hub 160and the tip 150 form a fluid-tight engagement.

In accordance with one or more embodiments, the protrusion 175 isdisposed on the outer surface of the first indicating element 170 andmay be modified in shape and location to adjust the pre-determined forcerequired to form a fluid-tight engagement between the hub 160 and thetip 150. For example, the height of the protrusion 175 may be increasedto increase the total amount of force needed to be applied on the hub160 and/or the fluid storage container 140 to form a fluid-tightengagement between the hub 160 and the tip 150. The increased height ofthe protrusion 170 increases resistance to advancement of the secondindicating element 180 in the distal direction over the first indicatingelement 170. This increased resistance indicates to the user that moreforce is required to form such engagement between the hub 160 and thetip 150. Advancement of the second indicating element 180 into therecess 163 over the first indicating element 170 indicates sufficientforce has been applied to the hub 160 and/or fluid storage container 140to create fluid-tight engagement.

As more clearly shown in FIGS. 4-7, the second indicating element 180 isshaped to fit over the first indicating element 170 of the hub 160. Thehollow body 182 of the second indicating element 180 may be elongate andsolid. In one or more embodiments, the inside surface 184 of the hollowbody 182 adjacent to the distal end 189 and/or the proximal end 181 ofthe second indicating element 180 includes a solid, continuous oruninterrupted perimeter 190 that defines the open distal end 189 and/orat the open proximal end 181. In a specific embodiment, the insidesurface 184 and/or the outside surface of body 182 may be free ofinternal threads. In one or more embodiments, the inside surface 184 isshaped to form a hollow interior 186 that can envelope the firstindicating element 170 as the second indicating element 180 advancesdistally over the first indicating element 170. It will be understoodthat the body 182 extending between the open proximal end 181 and theopen distal end 189 of the second indicating element 180 need not besolid and may include openings that allow access to the hollow interior186 from the open distal end 189, open proximal end 181 or along thebody 182, however, the solid perimeter 190 formed by the inside surface184 adjacent to the open distal end 189 and/or the proximal end 181 iscontinuous.

The second indicating element 180 is disposed within the cavity 166 ofthe hub as a separate piece and is not attached or connected to the hubbefore engagement of the hub to a fluid storage container. In onespecific embodiment, the second indicating element 180 may be shapedsuch that it fits inside the cavity 166 of the hub 160. In a morespecific embodiment, the second indicating element 180 may be shaped soit is slidable and/or moveable within the cavity 166 of the hub 160. Ina more specific embodiment, the second indicating element 180 may beshaped so that it is not rotatable in any direction within the cavity166 of the hub 160. In an even more specific embodiment, the secondindicating element 180 is shaped to allow rotation only around the axisextending from the open distal end 189 and the open proximal end 181.

In one or more embodiments, the outside surface of body 182 has across-sectional width that permits the second indicating element 180 tofit within the cavity 166 of the hub 160 and the inside surface 184 atthe perimeter has a cross-sectional width that permits the secondindicating element 180 to slide distally over the first indicatingelement 170. In a more specific embodiment, the body 182 has a thicknessthat allows the second indicating element 180 to advance distally withinthe recess 163 of the hub 160. The body 182 shown more clearly in FIGS.4-7 forms a cylinder having a solid circular cross-section along itsentire length and includes a continuous solid perimeter 190 at thedistal end 189 and the proximal end 181.

It will be understood that the first and second indicating elements mayhave cross-sections of any shape. In one or more embodiments, the firstand/or second indicating element may have a cross-section such that theinside surface of the first and/or second indicating element forms anon-circular shape and the outside surface of the first and/or secondindicating element forms a circular shape. In a specific embodiment, thefirst and/or second indicating element may have a cross-section suchthat the inside surface forms a circular shape and the outside surfaceforms a non-circular shape. In embodiments wherein the first and/orsecond indicating elements have a non-circular cross-section, it will beunderstood that the medical device assembly may include a means tocontrol orientation of the second indicating element with respect to thefirst indicating element.

In a more specific embodiment, the outside surface of the body 182includes an outwardly radially extending lip 183 or projection disposedat one or more points along the length of the outside surface of thebody 182. The lip 183 may be disposed near the distal end 181 and/orproximal end 189 of the second indicating element 180. Alternativeembodiments may include a second indicating element 180 may include aplurality of lips disposed along the outside surface of the body 182.The lip 183 may be a single protruding point extending outwardlyradially from the outside surface of the body 182 or may be peripherallyformed around the outside surface of the body 182, as shown in FIGS.4-7.

In one or more embodiments, the lip 183 increases the thickness of thebody 182. In a specific embodiment, the cross-sectional width of thesecond indicating element 180 at lip is greater than the cross-sectionalwidth of the second indicating element 180 at the exterior surface ofthe second indicating element 180 at remaining portions of the body 182.As more clearly shown in the embodiment of FIG. 10, the increasedcross-sectional width formed by the lip 183 forms a interference orfriction fit interaction with the sidewall 164 of the hub 160 so thatthe second indicating element 180 is retained within the cavity 166 ofthe hub 160 before engagement of the medical device assembly and a fluidstorage container, when forming a fluid delivery system 100.

In one or more embodiments, the inside surface 184 has a cross-sectionalwidth, which is measured at the inside surface 184, that forms aninterference fit with the outside surface of the first indicatingelement 170. As will be described in greater detail, the inside surface184 of one or more embodiments of the second indicating element 180defines a gradually tapered cross-sectional width that forms a narrowedportion at one or more points along the length of the inside surface184. More specifically, the inside surface 184 may be shaped to includea first cross-sectional region defining the narrowest cross-sectionalwidth. In a more specific embodiment, the inside surface 184 may beshaped to include a second cross-sectional region that defines across-sectional width measured at the inside surface 184 that is greaterthan the cross-sectional width at the first cross-sectional region thatextends distally and/or proximally from the first cross-sectionalregion. In one or more embodiments, the second cross-sectional regionmay include a cross-sectional width that increases as it extendsdistally and/or proximally from the first cross-sectional region. Inalternative embodiments, the inside surface 184 may be shaped to includea third cross-sectional region that has a cross-sectional width measuredat the inside surface 184 that is greater than the cross-sectional widthof the first and second cross-sectional regions. The thirdcross-sectional region may be disposed adjacent to the proximal end 181and/or the distal end 189 of the second indicating element 180. In oneor more embodiments, the third cross-sectional region may have across-sectional width that increases or decreases along its length. Thethird cross-sectional region may be disposed adjacent to the secondcross-sectional region and the proximal end 181 and/or distal end 189 ofthe second indicating element 180.

In the embodiment shown in FIGS. 4-7, the second indicating element 180includes a circular cross-section and has an inside surface 184 defininga first diameter region 185 that may have a narrowed cross-sectionalwidth or diameter measured along the circumference of the inside surfaceat one or more points along the axial length of the body 182. In one ormore embodiments, the first diameter region 185 is a tapered portionthat has a cross-sectional width that gradually decreases, with respectto the cross-sectional width defined by the remaining portions of theinside surface 184 of the second indicating element 180. The secondindicating element 180 may also include a second diameter region 187 atone or more points along the axial length of the inside surface 184 thatextends from the first diameter region 185 toward the distal end 189and/or the proximal end 181 of the second indicating element 180. In oneor more embodiments, the inside surface 184 includes a first diameterregion 185 adjacent the open distal end 189 of the second indicatingelement 180 and a second diameter region 187 having an axial lengthextending from the first diameter region 185 to the open proximal end181 such that the diameter of the inside surface 184 increases along thesecond diameter region 187 from the first diameter region 185 toward theproximal end 181. In such embodiments, the second diameter region 180forms a ramp or ramped portion having a proximally increasing diametermeasured at the inside surface 184. In a specific embodiment, the firstdiameter region 185 is disposed adjacent to the proximal end 181 of thesecond indicating element 180 and the second diameter region 187 extendsdistally toward the distal end 189 of the second indicating element 180.

The inside surface 184 of the second indicating element 180 may alsoinclude a third diameter region 188 that has a diameter greater than thediameter at the first diameter region 185 and the diameter at the seconddiameter region 187. In one or more embodiments, the third diameterregion 188 has a diameter that is constant along its entire length. In aspecific embodiment, the third diameter region 188 has a diameter thatincreases along its length in the proximal or distal direction.

In embodiments which utilize a first diameter region 185, a seconddiameter region 187 and a third diameter region 188, the second diameterregion 187 has a diameter that is greater than the diameter of the firstdiameter region 185 and a diameter that is smaller than the diameter ofthe third diameter region 188. In one or more embodiments, the secondindicating element 180 includes a first diameter region 185 disposedadjacent to the distal end 189, second diameter region 187 disposedproximally adjacent to the first diameter region 185 and a thirddiameter region 188 disposed proximally adjacent to the second diameterregion 187 and extending toward the proximal end 181. In a more specificembodiment, the diameter of the second diameter region 187 increases asit extends from the first diameter region 185 to the third diameterregion 188. In an even more specific embodiment, the third diameterregion 188 has a diameter that increases along its length in the distalor proximal direction.

In one or more embodiments, the third diameter region 188 has a diametermeasured at the inside surface 184 that is sized to prevent the tip 150of the fluid storage container 140 from entering or being inserted intothe hollow interior 186 of the second indicating element. In embodimentsof the second indicating element 180 that are composed of a plastic orpolymeric material, the third diameter region 188 is sufficiently rigidto provide support to the second indicating element 180 to preventdeformation during use or, more specifically, upon application of aforce on the hub and/or fluid storage container that causes the secondindicating element 180 to advance distally over the first indicatingelement 170 and/or the protrusion 175. The third diameter region 188 ofa specific embodiment may also have a diameter equal to or larger thanthe diameter of the first indicating element 170 and/or the diameterformed by the protrusion 175 and the first indicating element 170. Inone or more embodiments, the diameter of the third diameter region 188is greater than the diameter formed by the protrusion 175 such that thethird diameter region 188 is permitted to advance distally past theprotrusion 175. In such embodiments, advancement of the third diameterregion 188 distally past the protrusion 175 indicates fluid tightengagement of the medical device and the fluid storage container andthat no residual or additional force should be applied to the hub 160 inthe proximal direction toward the fluid storage container or to thefluid storage container 140 in the distal direction toward the hub 160.

The first diameter region 185 forms an entrance angle 178 at the distalend 189 of the second indicating element 180 that permits the secondindicating element 180 to move distally over the first indicatingelement 170, while forming line contact with the first indicatingelement 170 and the protrusion 175. It will be understood that prior toactivation, line contact may be formed between the entrance angle 178and the first indicating element 170. In a specific embodiment, theentrance angle 178 also forms line contact with the protrusion 175. In amore specific embodiment, line contact may be formed between theentrance angle 178 and the first diameter region 185 and the firstindicating element 170 and the protrusion 175.

As shown in the movements of the first and second indicating elements170, 180 in FIGS. 10-17, the second indicating element 180 forms one ormore line contact interactions with the first indicating element 180and/or protrusion 175 as the second indicating element 180 enters therecess 163 and slides distally over the first indicating element 170. Asshown in FIGS. 12-13, one or more line contact interactions are formedfrom the point at which the first indicating element 170 contacts theentrance angle 178 of the second indicating element 180. In one or moreembodiments, the firsts indicating element 170 bends radially inwardlyand permits the second indicating element 180 to further advancedistally into the recess 163 while line contact is maintained betweenthe first indicating element 170 and the second indicating element 180.As a proximally directed force is applied to the hub 160 toward thefluid storage container 140 or a distally directed force is applied tothe fluid storage container 140 toward the hub 160, the secondindicating element 180 continues to advance distally past the firstindicating element 170 and forms one or more line contact interactionswhen the first indicating element 170 and/or protrusion 175 contacts thefirst diameter region 185 of the second indicating element 180, as shownin FIGS. 14-15. As the user continues to apply a proximally directedforce to the hub 160 toward the fluid storage container 140 or adistally directed force is applied to the fluid storage container 140toward the hub 160, one or more line contact interactions are formed asthe first indicating element 170 and/or protrusion 175 contacts thesecond diameter region 187 and/or the third diameter region 188 of thesecond indicating element 180, as shown in FIGS. 16-17. In one or moreembodiments, as the second diameter region 187 advances distally pastthe protrusion 175 and the third diameter region 188 begins to advancedistally past the protrusion 175, line contact is no longer maintained.According to one or more embodiments, once the second indicating element180 has moved distally past the protrusion 175 of the first indicatingelement, the protrusion 175 retains the second indicating element 180within the recess 163 by preventing 180 and, specifically the firstdiameter portion 185, from moving in the proximal direction.

In a specific embodiment, the entrance angle 178 formed between firstdiameter region 185 at the distal end 189 of the second indicatingelement 180 has a radius that is larger than the height of theprotrusion 185. In such embodiments, the larger radius of the secondindicating element ensures the second indicating element 180 advancessmoothly distally past the protrusion 175

According to one or more embodiments, the solid perimeter 190 formed byinside surface 184 of the second indicating element at the distal end189 and the proximal end 181 maintains its shape or resists deformationas the second indicating element 180 moves distally over the firstindicating element 170 and protrusion 175. The solid perimeter 190 ofthe second indicating element 180 forms a contact area between theinside surface 184 and the outside surface of the first indicatingelement 170 and/or the protrusion 175. For example, in embodiments whichutilize a cylindrical second indicating element 180, the solid perimeter190 maintains a circular shape as the second indicating element 180moves distally over the first indicating element 170 and protrusion 175and forms a circular contact area between the inside surface 184 and theoutside surface of the first indicating element 170. In one or moreembodiment, the rigidity of the solid perimeter 190 ensures that thesecond indicating element 180 maintains its shape and thus allows use ofthe medical device assembly with fluid-storage containers that requirehigher or increased engagement force to form a fluid-tight engagementbetween the medical device assembly and the fluid storage container 140.Interruptions in the solid perimeter 190 formed by the inside surface184 at the distal end 189 and/or proximal end 181 of the secondindicating element 180 cause the second indicating element 180 to deformas it moves distally over the first indicating element 170 andprotrusion 175, causing variability in engagement forces required toconnect the hub 160 and fluid storage container 140 in fluid-tightengagement. For example, the presence of interruptions in the solidperimeter 190 formed by the inside surface 184 of a second indicatingelement 180 having a cylindrical shape may cause the body 182 to deformsuch that the cross-section of the body 182 changes from a circularshape to an ellipsoidal shape. In another example, where the secondindicating element 180 has a regular polygonal shape, interruptions inthe solid perimeter 190 formed by the inside surface 184 may deform thebody such that the cross-section of the body 182 changes from a regularpolygonal to an irregular polygonal.

Interaction between non-conformal surfaces creates either a line orsurface contact. The tapered geometry of the embodiments of the secondindicating element 180 allows the formation of line contact interactionsbetween the second indicating element 180 and the first indicatingelement 170. Line contact interactions distribute the stress andpressure applied to both surfaces among more than one point or location.This reduces the stress applied to any single point thereby reducinglikelihood that a defect in one or both of the surfaces will result in afailure of the structural integrity of either part. Medical deviceassemblies which do not have a tapered second indicating element arelikely to form only point or surface contacts with the first indicatingelement. In these assemblies the stress or force applied to bothsurfaces is not distributed According to one or more embodiments of thepresent invention, the inside surface 184 of the second indicatingelement 180 is further contoured to maintain line-contact with the firstindicating element 170 as the second indicating element 180 movesdistally over the first indicating element 170 and the protrusion 175.In one or more embodiments, once the second diameter region 187 advancesdistally past the protrusion 175, there is no contact between theprotrusion 175 and second indicating element 180. Specifically, theentrance angle 178, first diameter region 185, second diameter region187 and the third diameter region 188 are shaped to create line contactbetween the second indicating element 180 and the first indicatingelement 170 and the protrusion 175 throughout the range of distalmovement of the first diameter region 185 and second diameter region 187distally past the protrusion 175 of the first indicating element

An alternative embodiment of the second indicating element 380 is shownin FIG. 8. The second indicating element 380 has a body 382 extendingfrom an open distal end 389 to an open proximal end 381. The body 382includes an inside surface 384 defining a hollow interior 386 and a lip383 outwardly radially extending from the outside surface of the body382. The inside surface 384 includes a tapered portion 385 adjacent theopen distal end 389, a ramped portion 387 proximally adjacent to thetapered diameter portion 385, an enlarged portion 388 adjacent the openproximal end 381. The ramped portion 387 has an axial length extendingfrom the tapered portion 385 toward the enlarged portion 388 such thatthe cross-sectional width measured at the inside surface 384 increasesalong the ramped portion 387 from the tapered portion 385 toward theenlarged portion 388. In this embodiment, the length of the rampedportion 387 is reduced in length such that the change in cross-sectionalwidth measured at the inside surface 384 at the tapered portion 385 andthe enlarged portion 388 is more abrupt or less gradual. In suchembodiments, fluid-tight engagement of the hub and the fluid storagedevice provides more noticeable tactile feedback, while maintaining oneor more line contact interactions between the first indicating elementand the second indicating element 380. For example, upon advancement ofthe tapered portion 385 distally past the first indicating element andthe protrusion creates a snappier or crisper engagement. This enhancedtactile feedback is believed to be produced from the expansion of thecross-sectional width measured from the inside surface 384 uponadvancement of the tapered portion 385 distally past the protrusion withmore rapid alignment of the protrusion with the enlarged portion 388.

The second indicating element of one or more embodiments describedherein may be formed from a plastic material or from metal. In one ormore embodiments, the second indicating element is injection moldedusing an injection moldable plastic such as polypropylene, polyethylene,polycarbonate or combinations thereof. As discussed above, the insidesurface of the second indicating element forms one or more line contactinteractions as the second indicating element advances distally over thefirst indicating element. It is believed that line contact interactionsreduce sensitivity to molding defects on the protrusion and/or the firstindicating element. The line contact interactions are also believed toreduce deformation of the inside surface of embodiments of secondindicating element as it passes distally over the protrusion.

Previous attempts at providing a means for indicating fluid-tightengagement often utilize elements with abrupt changes in diameter,structural angles and contact interactions, to provide sufficienttactile feedback to the user. Such attempts discouraged the use of moregradual changes in diameter or other structural features. These attemptsalso utilize rigid materials to enhance tactile feedback and incorporatestructural gaps in the body of the elements to accommodate for potentialskiving and unpredictable engagement forces that may result from therigidity and/or stiffness of the materials utilized. Further, the needto produce tactile feedback also limits the range of materials that canbe used to produce the desired structures

Previous attempts at improving connection mechanisms for securelyconnecting a hub to fluid storage containers in fluid-tight engagementand mechanisms to indicate such engagement between a hub and fluidcontainer have focused on modifying the type of materials utilized forthe first and/or second indicating elements. Modifying materials wasalso thought to result in additional benefits such as reducing theweight of the medical device assembly and allowing the use of othermethods of production, such as molding, that can increase productioncapacity more easily than other methods of production, such as stampingused to form metallic components. The variation in production methodsalso permits a greater selection of materials. Specific attempts atmodifying the materials used to form the first and/or second indicatingelements focused on using a more rigid plastic material to manufacturethe first and/or second indicating elements. Such materials werebelieved to provide a better indicator of the engagement force needed toform fluid-tight engagement between the hub and the fluid storagecontainer. In such attempts, however, the more rigid plastic did nothave a direct consequence on the engagement forces needed for thefluid-tight engagement of the hub to the fluid storage container.Further use of varying materials caused additional problems such asvariability in engagement forces of the first indicating element andsecond indicating element, which prevented accurate indication offluid-tight engagement between the hub and the fluid storage container.

Modifying the shape of the components, for example, by utilizing thetapered design for the second indicating element described herein,mitigated these problems. The solid perimeter 190 design of the secondindicating element further improved manufacturability and allowed theselection and use of more elastic materials, which reduces thedependency on exact dimensions. Further, the surface finishes of theoutside surface of the first indicating element and the inside surfaceof the second indicating element can be modified to ensure moreconsistent interaction between the first and second indicating elements.

In one or more embodiments, second indicating elements 180 manufacturedby injection molding are substantially free of structural projectionscaused by other manufacturing methods that have limited applicationbased on the material used. Such structural projections includeprojections that extend radially outwardly from the body at the distalend and/or proximal end, that may cause skiving of the hub or otherincreases in the engagement force required to form a fluid-tightengagement between the hub and tip.

In one or more embodiments, the sidewall 164 of the hub, the firstindicating element 170 and/or the second indicating element 180 may alsobe shaped and configured to reduce dead space or unoccupied spacebetween the tip 150 and the passageway 130. In previous attempts at aconnection mechanism to indicate fluid-tight engagement between the huband the fluid-storage container, gaps were included in the perimeter atthe openings of the second indicating element as a result of limitedproduction means and materials. In such embodiments the open gapsresulted in increased dead space within the hub when attached to a fluidstorage device. Embodiments of the second indicating element 180 whichinclude a solid and continuous body 182 reduce dead space within thecavity when the hub is attached to the fluid-storage device. In one ormore embodiments, the length of the first indicating element 170 may beadjusted to permit the distal end of one or more embodiments of thesecond indicating element described herein to advance into the recess163 formed between the first indicating element 170 and the sidewall 164until it contacts the distal end 169 of the hub 160. In suchembodiments, the length of the first indicating element 170 and themovement of the distal end of the second indicating element provideadditional indication of fluid tight engagement between the hub 160 andthe tip or fluid storage container by preventing the user from applyinga force on the hub in the proximal direction or the fluid storagecontainer in the distal direction. In an alternative embodiment, thelength of the first indicating element 170 may be adjusted to allow theuse of second indicating elements having different lengths. In one ormore embodiments, the length of the first indicating element 170 issufficiently long to permit the second indicating element to advancedistally past the protrusion 175 without interference or being blockedby the distal end 169 of the hub 160. Alternatively, the length of thebody 182 of the second indicating element 180 may be reduced to reducedead space between the tip 150 and the passageway 130 The sidewall 164may also be adjusted or modified to reduce or increase the length and/ordimensions of the recess 163, however, the length of the recess 163should permit the second indicating element 180 to advance distally pastthe protrusion 175.

An alternative embodiment of the hub 360 is shown in FIGS. 18A and 18B.The hub 360 includes a sidewall 364 and a first indicating element 370that is flexible and which forms a recess 363 with the sidewall 364. Asthe user applies the pre-determined force on the hub 360 to form afluid-tight engagement between the hub 360 and a fluid storagecontainer, the first indicating element 380 flexes inwardly toward thepassageway 330 to permit the body 382 of the second indicating elementto advance distally over the first indicating element 370 and/orprotrusion 375 into the recess 363. The ability of the first indicatingelement 370 to resume its original shape creates a tactile feedback forthe user of fluid-tight engagement between the hub 360 and the fluidstorage container. As shown in FIGS. 18B and A, the ramped portion 387of the second indicating element 280 has a reduced length that resultsin a more dramatic increase in diameter or cross-sectional widthmeasured at various points along the inside surface of the secondindicating element. In such embodiments, the first indicating element ispermitted to flex and relax more rapidly thereby producing enhancedtactile feedback for the user of fluid-tight engagement between the huband the fluid storage container.

According to an alternative embodiment, the body of the secondindicating element may be flexible and may flex as the second indicatingelement advances distally over the first indicating element and/orprotrusion. In such embodiments, the solid perimeter may be rigid andretains its shape as the second indicating element advances distallyover the first indicating element. In a more specific embodiment, one ofthe first indicating element and the second indicating element hasgreater flexibility that the other of the first indicating element andthe second indicating element. In an even more specific embodiment, oneof the first indicating element and second indicating element isflexible while the other of the two is relatively inflexible incomparison to the flexible element.

In embodiments where there is gradual increase in diameter orcross-sectional width measured at various points along the length of theinside surface of the second indicating element, the first indicatingelement and/or the second indicating element can provide tactilefeedback through the use of different materials with differentflexibility or rigidity that permit the flexed element to resume itsoriginal shape after the second indicating element advances distallypast the protrusion of the first indicating element.

A second aspect of the present invention pertains to an indicationsystem for use with the medical device assemblies described hereinduring attachment to a fluid storage container, for example, the fluidstorage container 140 shown in FIG. 1. The indication system providesvisual indication of optimal engagement or optimal degree of press-fitor interference fit has been achieved during connection of the hub, forexample, the hub 160 shown in FIG. 1, and the fluid storage container.Specifically, the indication system provides visual indication ofover-tightening, under-tightening and optimal tightening of the luerslip connection between hub 160 and the fluid storage container 140.Over-tightening of the hub 160 and fluid storage container luer slip maycause excessive compressive force at the joint or mating interfacebetween the hub 160 and fluid storage container 140. This excessivecompressive force can later require the user to apply a large amount offorce to disassemble the hub 160 from the fluid storage container 140.Under-tightening of the hub 160 and fluid storage container luer slipconnection may compromise the effectiveness of the fluid-tightengagement or seal formed by the connection and may result in leakage ofthe medication being delivered from within fluid storage containerthrough the hub 160 or even complete separation of the hub 160 from thefluid storage container 140.

The indication system of the embodiment shown in FIGS. 19-22 includes avisual indicator 400 that is added to the fluid storage container 440,for example, along the circumference of the tip or opening of the fluidstorage container 440. In one or more embodiments, the visual indicatoris a colored region that is printed or over-molded onto the fluidstorage container. Other means known in the art may be utilized to applyor form the visual indicator on the fluid storage container 440. Duringattachment of the hub 460 to the fluid storage container 440, a force isapplied to the hub 460 in the proximal direction relative to the fluidstorage container 440. After application of the force, the position ofthe hub 460 relative to the visual indicator 400 indicates whetheradequate force has been applied to the hub to obtain optimal tightening.As shown more clearly in FIG. 20, optimal engagement is indicated byalignment of the visual indicator 400 directly adjacent to the hub 460.FIG. 21 illustrates overlap of the visual indicator 400 and hub 460indicating an over-tightened connection between the hub 460 and thefluid storage container 440. FIG. 22 illustrates a space between thevisual indicator 400 and the hub 460, indicating an under-tightenedconnection between the hub 460 and the fluid storage container 440.

In a specific embodiment, the visual indicator 400 includes threeseparate stripes (not shown) formed at three different locations fromnear the opening of the fluid storage container and proximally along thelength of the fluid-storage. In a more specific embodiment, the threestripes may have different colors. In such embodiments, the first stripedisposed closest to the opening of the fluid storage container is thefirst stripe and may be red in color, the second stripe disposedproximally adjacent to the first stripe may be green in color and thethird stripe disposed proximally adjacent to the second stripe may beyellow in color. As a force is applied to the hub in the proximaldirection toward the fluid storage container or a force is applied tothe fluid storage container in the distal direction toward the hub,visibility of the first, second and third stripes (or the red, green andyellow stripes) indicates under tightening and that additional forcemust be applied to the hub and/or fluid storage container. Visibility ofthe second and third stripes (or the green and yellow stripes) indicatesoptimal tightening while visibility of only the third stripe (or theyellow stripe) indicates over tightening. In one or more embodiments,the indication system of FIGS. 19-22 may be useful in providing visualindication of fluid-tight engagement between the medical assembliesdescribed herein that provide reduced tactile feedback of fluid-tightengagement. Examples of such embodiments assemblies with a secondindicating element 180 that does not include a third diameter region 188or that includes a second diameter region 187 having a lengthsufficiently long enough that the change in diameter from the firstdiameter region and the remaining length of the second indicatingelement is gradual or less abrupt. Alternatively, the indication systemof FIGS. 19-22 may also be utilized with embodiments with enhancedtactile feedback to provide an additional indication of fluid-tightengagement between the medical device assembly and the fluid storagecontainer.

A third aspect of the present invention pertains to methods of using themedical devices described herein. In one or more embodiments, the methodincludes providing a hub including a sidewall having an inside surfacedefining a cavity, an open proximal end, a distal end having an openingtherethrough in fluid communication with the cavity and a secondindicating element disposed within the cavity. The method furtherincludes positioning the hub such that the open proximal end is alignedwith the opening of a fluid storage container and applying a proximallydirected force on the hub or applying a distally directed force on thefluid storage container such that the opening of the fluid storagecontainer is disposed within the cavity and abuts the second indicatingelement. The method further includes applying a continuous force in theproximal direction on the hub and/or in the distal direction on thefluid storage container to force the second indicating element toadvance distally further into the cavity and engage with the hub. Inembodiments of the medical device which utilize a first indicatingelement extending from the distal end of the hub into the cavity, themethod includes applying a continuous force on the hub in the proximaldirection toward the fluid storage container and/or on the fluid storagecontainer in the distal direction toward the hub such that the secondindicating element envelopes the first indicating element and entersinto the recess formed between the first indicating element and the hub,until the hub and fluid storage device are in fluid-tight engagement.

Reference throughout this specification to “one embodiment,” “certainembodiments,” “one or more embodiments” or “an embodiment” means that aparticular feature, structure, material, or characteristic described inconnection with the embodiment is included in at least one embodiment ofthe invention. Thus, the appearances of the phrases such as “in one ormore embodiments,” “in certain embodiments,” “in one embodiment” or “inan embodiment” in various places throughout this specification are notnecessarily referring to the same embodiment of the invention.Furthermore, the particular features, structures, materials, orcharacteristics may be combined in any suitable manner in one or moreembodiments.

Although the invention herein has been described with reference toparticular embodiments, it is to be understood that these embodimentsare merely illustrative of the principles and applications of thepresent invention. It will be apparent to those skilled in the art thatvarious modifications and variations can be made to the method andapparatus of the present invention without departing from the spirit andscope of the invention. Thus, it is intended that the present inventioninclude modifications and variations that are within the scope of theappended claims and their equivalents.

What is claimed is:
 1. A medical device configured to be connected to atip of a fluid storage container, the medical device comprising: a hubincluding a sidewall having an inside surface defining a cavity, an openproximal end, and a distal end having an opening therethrough in fluidcommunication with the cavity; a first indicating element having adistal end attached to the distal end of the hub and a free proximal endextending into the cavity, the first indicating element forming aperipheral recess with the sidewall of the hub; and a second indicatingelement disposed in the cavity of the hub including an open proximalend, an open distal end and a body extending from the open proximal endof the second indicating element to the open distal end of the secondindicating element, the body having an outside surface and an insidesurface, the inside surface of the second indicating element defining ahollow interior extending from the open proximal end of the secondindicating element to the open distal end of the second indicatingelement, the outside surface of the body of the second indicatingelement including one or more lips disposed along one or more pointsalong a length of the outside surface of the body that prevents the bodyof the second indicating element from entering the recess until apre-determined distally-directed force is applied to the secondindicating element by the tip of the fluid storage container, the insidesurface of the second indicating element defining a gradually taperedcross-sectional width that provides the body with a narrowed portiondisposed adjacent to the proximal end of the second indicating elementsized to prevent the tip of the fluid storage container from beinginserted into the hollow interior upon application of the pre-determineddistally directed force to the second indicating element.
 2. The medicaldevice of claim 1, wherein the one or more lips comprise a protrudingpoint extending outward radially from the outside surface of the body.3. The medical device of claim 1, wherein the one or more lips isperipherally formed around the outside surface of the body.
 4. Themedical device of claim 1, wherein an increased cross-sectional width ofthe second indicating element is formed at the one or more lips.
 5. Themedical device of claim 4, wherein the increased cross-sectional widthforms an interference fit with the sidewall of the hub.
 6. The medicaldevice of claim 1, wherein the one or more lips increases a thickness ofthe body.
 7. The medical device of claim 1, wherein fluid-tightengagement of the hub and the fluid storage container produces tactilefeedback to a user of the medical device to indicate the fluid-tightengagement of the hub and the fluid storage container.
 8. The medicaldevice of claim 1, wherein the fluid storage container comprises asyringe.